Nanochannels with a 18-nm feature size and ultrahigh aspect ratio on silica through surface assisting material ejection

Lu, Yu; Lin, Kai‐Hsin; Chen, Caiyi; Qing, Yang; Meng, Yizhao; Liu, Yi; Yang, Cheng; Hou, Xun; Chen, Feng

doi:10.1117/1.apn.1.2.026004

Cited by 10 publications

(4 citation statements)

References 42 publications

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“…In addition, we can design the new coded aperture to match the H-STAR acquisition method in the future so that the number of channels can be slightly reduced to improve the field of view (FOV) of the entire system. This work will play an important role in the understanding of ultrafast processes such as femtosecond laser–matter interaction, − ultrashort pulse light field measurement, and atomic time scale. H-STAR will be a highly robust and suitable ultrafast imaging technique for studying transient, nonrepetitive events.…”

Section: Discussionmentioning

confidence: 99%

High-Channel Spectral-Temporal Active Recording (H-STAR) for Femtosecond Scenes Observation in a Single-Shot

Meng,

Liu,

Yin

et al. 2024

ACS Photonics

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Ultrafast compressed imaging is promising for capturing a large number of frames and providing single-shot observations of various unknown and important transient scenes. However, this technique often compromises spatial resolution in order to capture ultrafast phenomena with larger frame numbers. In this paper, a high-channel spectral-temporal active recording (H-STAR) is proposed, which achieves both femtosecond-level ultrafast imaging speed and high spatial resolution by substantially increasing the number of imaging channels. H-STAR can realize the highest spatial resolution of 101.6 lp/mm, the highest frame rate of 5.52 trillion frames per second, and the highest frame number of 120. The advantages of H-STAR, including its compact optical structure, high frame rate, large number of frames, and high imaging quality, are demonstrated through the capture of laser-induced plasma dynamics and the twice-reflection of the light spot. H-STAR enables single-shot and precise recording of ultrafast processes with both spatial and temporal complexity.

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Section: Discussionmentioning

confidence: 99%

High-Channel Spectral-Temporal Active Recording (H-STAR) for Femtosecond Scenes Observation in a Single-Shot

Meng,

Liu,

Yin

et al. 2024

ACS Photonics

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“…FsL has the capability of cold machining due to its ultra-short pulse and ultra-high peak power and has significant application value in the field of micromaching. [37][38][39][40][41][42][43][44] The advantages of the FsL fabrication for microstructures are analyzed in Note S3 (Supporting information). Figure 2a shows the fabrication process of the LM-based capacitive pressure sensor.…”

Section: Design and Characterization Of All-soft Sensorsmentioning

confidence: 99%

Wireless, Smart Hemostasis Device with All‐Soft Sensing System for Quantitative and Real‐Time Pressure Evaluation

Zhang,

Yang,

Meng

et al. 2023

Advanced Science

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The properly applied pressure between the skin and hemostasis devices is an essential parameter for preventing bleeding and postoperative complications after a transradial procedure. However, this parameter is usually controlled based on the subjective judgment of doctors, which might cause insufficient hemostatic effect or thrombosis. Here this study develops a compact and wireless sensing system for continuously monitoring the pressure applied on the radial artery and wrist skin in clinical practice. A liquid metal (LM)‐based all‐soft pressure sensor is fabricated to enable conformal attachment between the device and skin even under large deformation conditions. The linear sensitivity of 0.007 kPa−1 among the wide pressure range of 0–100 kPa is achieved and the real‐time detection data can be wirelessly transmitted to mobile clients as a reference pressure value. With these devices, detailed pressure data can be collected, analyzed, and stored for medical assistance as well as to improve surgery quality.

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“…Similar high-pressure conditions were observed for zero-order Bessel beam, leading to the generation of nano-spheroid on YAG [43] and in nano-channel formation with the so-called surface assisted material ejection. [44] Depending on the laser-deposited energy, the material at the center of the tube core can be in different physical states. As highlighted before, the three regimes we have identified depend on the fluence at the exit surface.…”

Section: Formation Mechanism Of the Nano-pillarsmentioning

confidence: 99%

“…Similar high‐pressure conditions were observed for zero‐order Bessel beam, leading to the generation of nano‐spheroid on YAG [ 43 ] and in nano‐channel formation with the so‐called surface assisted material ejection. [ 44 ]…”

Section: Formation Mechanism Of the Nano‐pillarsmentioning

confidence: 99%

Single Shot Generation of High‐Aspect‐Ratio Nano‐Rods from Sapphire by Ultrafast First Order Bessel Beam

Belloni,

Hassan,

Furfaro

et al. 2023

Laser & Photonics Reviews

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Engineering the polarization and spatial phase of ultrafast laser pulses represents a compelling strategy for enhancing control over laser–matter interaction and enabling rapid and innovative nano‐fabrication processes. Here, the single‐shot, ultrafast laser fabrication of high‐aspect‐ratio, vertically standing nano‐pillars with a diameter of ≈800 nm and height up to 15 µm on the surface of sapphire, is reported. To achieve this, the distinctive properties of diffraction‐free, first‐order Bessel beams endowed with either radial or azimuthal polarization distributions, are harnessed under tight focusing conditions. The highly intense laser–matter interaction in this configuration generates a tubular‐shaped, high‐pressure field beneath the material surface, leading to the rapid expulsion of material across the surface. Three distinct regimes for the pillar generation are identified in addition to a mechanism based on the Rayleigh‐Plateau theory that explains the distinct morphological regimes observed. The findings not only shed light on the underlying physical mechanisms of intense excitation of transparent dielectrics but also offer exciting prospects for the rapid fabrication of positive nano‐structures and material compression across various fields of application.

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Nanochannels with a 18-nm feature size and ultrahigh aspect ratio on silica through surface assisting material ejection

Cited by 10 publications

References 42 publications

High-Channel Spectral-Temporal Active Recording (H-STAR) for Femtosecond Scenes Observation in a Single-Shot

High-Channel Spectral-Temporal Active Recording (H-STAR) for Femtosecond Scenes Observation in a Single-Shot

Wireless, Smart Hemostasis Device with All‐Soft Sensing System for Quantitative and Real‐Time Pressure Evaluation

Single Shot Generation of High‐Aspect‐Ratio Nano‐Rods from Sapphire by Ultrafast First Order Bessel Beam

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